Method and apparatus for system design

ABSTRACT

A system level automation tool for system design using a computer is operable to generate a first set of objects each defining a portion of the system. The objects have a parent-child relationship wherein one or more child objects each define a portion of the parent object. A second set of implementable objects is associated with the first set of objects using a transitional mapping (TRAM) describing the relationships between the first and second sets of objects.

RELATED PATENT APPLICATIONS

This patent application is related to U.S. patent application Ser. No.08/075,884 (Attorney's Docket No. TI-15623), entitled "Computer Tool ForSystem Level Design"; U.S. patent application Ser. No. 07/966,128(Attorney's Docket No. TI-15491, entitled "Method and apparatus forAiding System Design"; and U.S. patent application Ser. No. 07/965,984(Attorney's Docket No. TI-15334), entitled "Method and Apparatus ForTracking Allocatable Requirements", all filed concurrently herewith.

TECHNICAL FIELD OF THE INVENTION

This invention relates in general to computers systems and moreparticularly, to a computer system automation tool for system levelengineers.

BACKGROUND OF THE INVENTION

System engineering concerns the conceptualization and construction ofcomplex systems. As such, it is an important part of any major project.The system engineering commences at the initial stages of a project, andcontinues throughout the project life cycle, thereby having a greatimpact on the successful completion of the project.

To aid the system engineer, a multitude of computer tools have beendesigned. One word which is the key to understanding these tools is"system". Webster's generic definition describes a system as "aregularly interacting or independent group of items forming a unifiedwhole." "Systems" range from extremely high-level concepts such as "amotorized vehicle for individuals" to the low-level, such as "a drivetrain."

Although the term "system" is an overloaded term which can havefar-reaching implications, an important element to consider is thedifferent types of support tools which are appropriate at differentsystem levels. Current software (e.g., CASE--Computer Aided SoftwareEngineering) and hardware (e.g., CAE--Computer Aided Engineering) designtools are directed toward efficiency of use in a specific environment,rather than over the broad range of system levels. As such, severaldifferent tools are necessary at the different system levels, whichcomplicates communication of necessary information between systemlevels. Further, the specific tools place different operationalrequirements on the user, thereby reducing the efficiency of using theprograms.

Therefore, a need has arisen in the industry for a system engineeringtool which provides engineering support over a wide range of systemlevels.

SUMMARY OF THE INVENTION

In accordance with the present invention, a method and apparatus foraiding system design with a computer which substantially overcomesproblems associated with prior system engineering tools.

The present invention is operable to generate a first set of objects,each defining a portion of the system. The objects may have aparent-child relationship wherein one or more child objects each definea portion of the parent object. A second of set of implementable objectsassociated with the first set of objects may be generated along withlinks between the first and second sets. The links describe arelationship between the first and second sets of objects.

In other aspects of the present invention, the links may traceapportioned allocatable and structural requirements between the firstand second sets of objects. A text file may be associated with each ofthe links to document the relationships.

The present invention provides significant advantages over the prior artin that mappings of functional requirements to implementable conceptsmay be identified and documented, along with preserving the traceabilityof structural and allocatable requirements through the system design.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and theadvantages thereof, reference is now made to the following descriptionstaken in conjunction with the accompanying drawings, in which:

FIG. 1 illustrates a block diagram of project functions performed by asystem engineer;

FIG. 2 illustrates a more detailed block diagram of a typical systemengineering cycle;

FIG. 3 illustrates a perspective view of a preferred hardware embodimentfor the present invention;

FIG. 4 illustrates an abstract model of the engineering cycle to whichthe present invention applies;

FIG. 5 illustrates a system level abstraction block (SLAB);

FIG. 6 illustrates a user interface showing hierarchical decompositionof a requirements definition;

FIGS. 7a-b illustrate a use for defining a technical allocation budget(TAB);

FIG. 8 illustrates a block diagram of an executable SLAB;

FIGS. 9a-d illustrate menus used for text fragments and automaticdocument generation;

FIG. 10 illustrates a block diagram of a transitional mapping (TRAM);

FIGS. 11a-b illustrate common uses of TRAMs; and

FIG. 12 illustrates an implementation of a mapping of regional TRAMs andrequirements (MORTAR).

DETAILED DESCRIPTION OF THE INVENTION

The preferred embodiment of the present invention and its advantages arebest understood by referring to FIGS. 1-12 of the drawings, likenumerals being used for like and corresponding parts of the variousdrawings.

FIG. 1 illustrates a block diagram showing the project functionsperformed by system engineers. The project 10 begins with conceptdefinition stage 12, which broadly states the goals of the project.Based on the output from the concept definition stage 12, a functionaldesign 14 is generated. From the functional design phase 14, a detaileddesign is developed in block 16. In block 18, a prototype is developed.After the prototype is developed, production of the units begins inblock 20. After production 20, maintenance and field support continue inblock 22. As can be seen by the block diagram of the project 10, thereis continuous feedback from the prototype production and maintenanceblocks 18-22 which is incorporated in the concept definition, functionaldesign and detailed design blocks 12-16.

FIG. 2 illustrates a more detailed block diagram of a typical systemengineering cycle. The system engineering cycle begins in block 24 withthe identification and evaluation of the operational needs of the systemunder consideration. These needs are combined with the customerrequirements in block 26 which are interpreted and prioritized in block28. This interpretation may be validated with the customer, after whichthe system requirements are designed in block 30.

The system requirements defined in block 30 are used to develop a systemdesign. The system design includes documentation on design tradeoffs,estimated performance, estimated costs, risks, maintenance plans,validation, and producibility. Further, the system design includes aproposed architecture, breaking down the system into logical groups. Forexample, in an electronics system, the architecture might be broken downinto analog, digital and software groups. If applicable, interfaces toother components must be defined. The information generated in thesystem design block 32 is reviewed in the system design review block 34.This is an interactive process in which the system design is refineduntil an acceptable design has been generated.

Once an acceptable design is generated, a design requirementsspecification is generated in block 36. The design requirementsspecification is reviewed under a preliminary design review block 38.The specification 36 is refined until accepted.

After the preliminary design review 38, a detailed design is developedin block 40 and a detailed design verification plan is developed inblock 42. The detailed design 40 is refined until accepted by a criticaldesign review 44. After accepted, the detailed design 40 is taken tofabrication and assembly 46. The system is tested in block 48 forperformance, maintenance, reliability and environmental factors.Information from the system testing 48 is used to refine the detaileddesign in block 40.

Once testing is complete, system integration and testing is performed inblock 50, the system is demonstrated in block 52, an operationalanalysis is performed in block 54 and the operational need (block 24) isvalidated in block 56.

As the cycle progresses from the concept stage to the design stage, thenumerous ancillary requirements often become apparent. Theserequirements are often written down in multiple places or carried in theheads of one or more people. Maintaining a consistent set ofrequirements among these documents and humans is a difficult problem.The system engineer continues to refine information, breakdownrequirements and define the functional structure of the solution. Systemlevel requirements need to flow downward in the hierarchy to ensure thatthe delivered system meets its requirements. Likewise, implementationdetails need to flow upward in the hierarchy in order to allow thesystem engineer to further refine the definition of the functionalstructure of the solution.

REQUIREMENTS

A large part of the system engineer's job involves informationmanagement. System level requirements are some of the most importantpieces of information to be managed. "Requirements" is a generalizedterm which is often loosely applied to a number of different types ofsystem level issues. The present invention provides support for fourbasic types of Requirements: Structural, Compliancy, Supplemental andAllocatable. "Structural" Requirements are statements in thespecification which describe a functional structure that must beembodied in the final product. An example of a Structural Requirementwould be "the database receives information through a bank oftwenty-four modems."

"Compliancy" Requirements are global compliancy statements relative tothe system being specified. For example, a specification might requirethat "all software development shall be done in Pascal," or "allelectronic hardware must be radiation hardened."

"Allocatable" Requirements are characterized by quantifiable measures.Quantities are typically described in such terms as weight, size, cost,pressure, temperature, speed, power, memory and process capacity and soon. These requirements typically impose limits on contributingcomponents of the product. Each of these requirements may be thought ofas part of the "technical budget." For example, if a system is allotted"twenty-five watts of power and must weigh no more than two pounds",then the weight and power must be allocated in the work breakdownstructure among all contributing components.

"Supplemental" Requirements are imposed on the system by virtue ofspecific implementation decisions. For example, the utilization of aparticular integrated circuit might limit operating temperatures for theentire system, even though the original specification did not have atemperature limitation. Additionally, Supplemental Requirements may beinternally imposed. For example, a particular company may have a policyagainst using parts made by a particular competitor, or may haveadditional requirements regarding documentation of the systemdevelopment. It is important that the Supplemental Requirements beuniquely identified so that when alternative implementations areconsidered, it is possible to identify quickly which requirements mightbe relaxed or removed, and under what conditions this would occur. AllSupplemental Requirements are further identifiable as Structural,Compliancy or Allocatable Requirements.

SYSTEM LEVEL AUTOMATION TOOL FOR ENGINEERS (SLATE)

FIG. 3 illustrates a perspective view of a preferred hardware embodimentfor the System Level Automation Tool for Engineers (SLATE) of thepresent invention. The user 58 inputs and receives information, such astext files, to a workstation 60 having a monochrome or color monitor 62and input devices such as a keyboard 64 and a mouse 66. The workstationshould be able to operate a graphical windowing system, such asX-windows. The workstation 60 is connected to a network in order toshare the information stored in its database with a plurality of users.

FIG. 4 illustrates a abstract model of the engineering cycle which SLATEaids in developing. The top level of this model is the FunctionalRequirement Definition ("FRD") 68. The FRD is a problem statement wherethe operational and other customer needs are collected. These needs arerefined into a set of system requirements. Each requirement can becategorized into one of the four types described hereinabove. Below theFRD level 68 is the Implementation Logically Mapped Alternatives("ILMA") group 70. Each ILMA 72 is a possible implementation of the FRD68. ILMAs 72 are bound to the FRD through a Functional to ImplementationMapping ("FIM") 74. There is only one FRD level 68 in a system, theremay be many ILMAs 72, one for each possible implementation alternative.Each ILMA 72 may be divided into functional categories 74 shown in FIG.4 as software, mechanical and hardware categories. The compliancychecklist 76 contains a list of compliancy requirements and ismaintained separate from the functional structures in SLATE.

SLABS

The base object in SLATE is the decomposition of the system into "SystemLevel Abstraction Blocks ("SLABs") 78, illustrated in FIG. 5. The SLABs78 can be thought of as a basic element of a functional block diagram.Each SLAB 78 has a unique identifier, such as "carburetor", supports"upwards" hierarchical links 80 to "parent" SLABs and "downward"hierarchical links 82 to "children" SLABs. Links between SLABs 78 ondifferent hierarchical levels is illustrated in greater detail inconnection with FIG. 6. Further, each SLAB supports functional links 84and 86, to and from peer SLABs, respectively. Peer SLABs are SLABs on acommon hierarchical level. The interrelation between peer SLABs is alsoshown graphically in connection with FIG. 6. Additionally, each SLAB 78supports Technical Allocation Budgets ("TABs") 88, RequirementsTraceability Links ("RTLs") 90, executable Functional Descriptions("FDs") 92 and text fragments 94. TABs 88 are used to maintain anaccount of quantifiable requirements which must be spread out amongvarious SLABs in a hierarchical level. For example, if a system has arequirement that the weight should be no greater than seven pounds, thenthe weight tab associated with a single hierarchical level should notexceed seven pounds.

SLATE supports two types of RTLs 90--structural RTLs and allocatableRTLs. A structural RTL links a text fragment relating to a structuralrequirement to a SLAB. For example, a proposed system for atransmitter/receiver may have a requirement that encoding shall beperformed using algorithm A and decoding shall be performed usingalgorithm B. An RTL would tie the text fragment containing theencoding/decoding requirements to a SLAB(s) which accommodates therequirement.

An allocatable RTL ties an allocatable requirement to a TAB definition.Allocatable RTLs are discussed further in connection with FIGS. 7a-b.

Text fragments 94 are one or more paragraphs of textual informationassociated with the SLABs 78. The text fragments 94 may be used for avariety of purposes, such as documentation, proposals, maintenanceinformation, manuals, and so on. The text fragments 94 may have anassociated description field identifying their purpose.

The executable functional descriptions 92 are used to compute outputsfrom inputs in order to test the functional operation of SLABs.Executable FDs are discussed in greater detail in connection with FIG.8.

FIG. 6 shows an illustration of the preferred embodiment of the userinterface for SLATE. The interface, referred to generally by referencenumeral 96 provides menu areas 98 each comprising a plurality of keys100 which may be selected using the mouse 66 or other input device. Thefunction of each of these keys will be described in greater detailhereinbelow. The interface 96 further provides a viewing area 100 whichmay be subdivided into a plurality of windows, shown as 102 and 104. Amessage area 106 is used to display messages from the system to theuser.

Window 102 illustrates the hierarchical decomposition of a concept intosystem components of increasing detail. The top level SLAB 106 has theID "Vending Machine." The vending machine concept has been broken downinto six (6) children SLABs 108-118. Children SLABs for Coin HandlingSLAB 114 are shown as SLABs 120-130. Changer SLAB 122 has two childrenSLABs 132 and 134. Change Supply SLAB 134 has four children SLABs136-142. Viewing area 104 illustrates the peer to peer connectionbetween the children SLABs 144-150 of the Product Handling SLAB 116.

TABS

An important aspect of the preferred embodiment is the TAB allocationfunction of SLATE. FIGS. 7a-b illustrate a pop-up menu used toconfigurate TAB for a particular SLAB. FIG. 7a illustrates a TAB 152 forthe vending machine SLAB 106 and FIG. 7b illustrates a TAB 154 for theProduct Inventory Chamber SLAB 110.

TABs 88 contain parametric information that describe the limits, goals,actual values and unit for quantifiable (allocatable) requirements.There are six pieces of information stored in a TAB, namely: maximumparameter limit, minimum parameter limit, goal parameter value, actual(calculated) parameter value, parameter confidence factor, and the unitthe parameter is expressed in (volts, amps, and so on). In many cases,only one of the maximum or minimum parameters will be used, for example,when a requirement sets forth a value which may not be exceeded.

SLATE design is built around hierarchical decomposition of systemblocks, as shown in FIG. 6. Each system level provides increasinglydetailed structures, until component level implementation detail isreached. System requirements normally mandate limits placed on higherlevels of system architecture structures (e.g., a system must not weighmore than twelve pounds), while the physical aspects that constitute theactual make-up of the parametric data (e.g., the microprocessor weighsfive ounces) normally are introduced at the lowest system design levels.Consequently, SLATE is designed to propagate the limits and goals foreach parametric requirement downwardly via the TABs 88 whilesimultaneously constructing actual/realized values upwardly through theTABs by summarization of the contributions of the children SLABs. Someconstraints, like reliability factors, require their own algorithmiccalculations and cannot be derived by simple summation.

A major difficulty in complex systems is that a stated allocatablerequirement is normally an aggregate limit placed on the overall systembehavior and/or composition, and the system engineer lacks the abilityto link the impact of design decisions made at lower levels, which areoften orders of magnitude removed from the initial allocation. Theproblem is further complicated upon recognition that the design isconstrained in multiple dimensions, i.e., one design parameter may actadversely upon another design parameter. For example, if a circuit needsto respond faster to meet a first requirement, one alternative may be touse higher powered components. However, more power consumption mayrequire more thermal dissipation which might affect another constraint,and an increase in cooling capacity might increase weight. The TABs 88associated with the various SLABs provide the ability to not only trackcomplexities, but to supply enough additional information within thelocalized context to aid the designer in understanding the availableoptions. In the previous example, it was stated that cooling capacitymight increase weight. However, by having the ability to track weightthroughout the SLABs, the system engineer may determine that anotherportion of the system has been allocated more weight (i.e., has a weightgoal) which is unnecessarily high based on a particular implementation.This may allow the system engineer to use higher powered componentswithout exceeding the weight constraint of the overall system.

The parameter value stored in each TAB must be recalculated whenever avariable (with regard to the equation field 188) or the Actual Valueassociated with a Child SLAB is changed, before contextual analysis canbe valid.

The system designer has the ability in SLATE to distribute the localparametric budget to each subcomponent in a logical manner. For example,if a unit has a maximum weight of five pounds, and is composed of threesubunits (each subunit represented on a SLAB), the designer mightallocate the TAB limits as one pound for the first subunit, one poundfor the second subunit and three pounds for the third subunit.Similarly, the designer might distribute the weight as two pounds forthe first subunit, three pounds for the second subunit and zero poundsfor the third subunit, if the third subunit has no weight, such as asoftware module. The designer also has the ability to hold some locallimit and/or goal in judgment for later allocation is needed. Limits andgoals are inserted for each SLAB and "flow down"; as a result, for eachSLAB in the system, a comparison can be made algorithmically betweengoals, limits and realized actuals. Actual conditions exceeding or evenapproaching limits and/or goals can be flagged for special attention bythe system engineer. Under utilized allocations for certain SLABs may beredistributed to SLABs exceeding the lower goals, as can portions of thebudget held in reserve (i.e., available but not allocated).

Each TAB 88 includes a confidence factor which indicates the degree ofcertainty that can be associated with the numeric quantity (estimatedversus measured). Thus, during TAB redistribution, limits on preciselymeasured TABs may be trimmed closely, while a larger margin of error canbe provided for TABs 88 with uncertain estimates, while still stayingwithin the overall system limit. Table I provides the certaintycategories from least certain (1) to most certain (10).

                  TABLE 1                                                         ______________________________________                                        Confidence Factors                                                            ______________________________________                                        1.         Uninitialized                                                      2.         Global default                                                     3.         Partition default                                                  4.         Computed from lower hierarchy                                      5.         Model specified                                                    6.         User specified                                                     7.         Special/other                                                      8.         Customer specified                                                 9.         Specified by standards                                             10.        Physical Law                                                       ______________________________________                                    

When calculating, the actual lowest valued confidence factor ispropagated up the hierarchical TABs thereby indicating how muchflexibility exists within or under a SLAB 78.

FIG. 7a and 7b illustrate pop-up menus 152 and 154 to define a TAB 88for a SLAB 78. Menus 152 and 154 each include a TAB Name Field 156, aSLAB Name Field 158, a TAB Units Field 160, a Goal Value Field 162, aMinimum Field 164, a Maximum Field 166, a TAB RTL Field 168 (whichpoints to an allocatable requirement) and an Actual Value Section 170.The Actual Value Section 170 allows the designer to select one of threemethods for determining the actual value of the TAB for the associatedSLAB. The designer may choose to determine the actual value through amathematical operation on corresponding TAB values associated with thechildren SLABs by using fields 172-178. A second method for providing anactual value is to use an assigned value using fields 180 and 182. Athird method is to determine the actual value by an equation usingfields 184-188. The chosen method is indicated by pointer 189.

Equation field 188 may be used to provide a equation by which the actualvalue may be determined. The actual value determined by the equation isoutput in field 184. Field 186 is a confidence value associated with thecomputed value.

The assigned value of field 180 may be input by the designer. TheConfidence Field 182 provides a confidence level associated with theAssigned Value.

The actual value may be computed based on a computation of the TABsassociated with the children SLABs. The designer enters the desiredoperation in field 174. Typically, the desired mathematical operationwill be a summation; however, other operations may also be provided. Forexample, to determine a reliability factor, a multiplication operationon the actual value associated with the children SLABs may be necessary.The confidence factor in field 176 is computed from the confidencefactors associated with the children SLABs.

FIG. 7a illustrates a menu which the designer has completed for the"weight" TAB. This TAB is associated with the vending machine SLAB 106,which is the top SLAB in the hierarchy. Therefore, the goal of 6,000pounds for the Weight TAB is an overall system goal. A minimum weight of5,000 pounds is specified and the maximum weight of 7,000 pounds isspecified. An Actual Value of 5,550 pounds is computed using the sum ofthe children SLABs. Thus, SLABs 108-118 each have associated Weight TABswhich total to 5,550 pounds.

FIG. 7b illustrates a "capacity" TAB associated with the ProductInventory Chamber SLAB 110. The goal is to provide a capacity of 550cans, with a minimum of 400 and a maximum of 700. In this instance, theActual Value of 545 cans is computed through an equation entered infield 188.

EXECUTABLE FUNCTIONAL DESCRIPTIONS (FDs)

FIG. 8 illustrates a block diagram showing the operation of anexecutable FD. As discussed in connection with FIG. 5, a SLAB 78 mayhave one or more executable FDs 92 which transform inputs into outputs.The executable FD 190 has two inputs "i" and "X" and two outputs "o" and"Y". Y represents a group of output signals and X represents a group ofinput signals; Y=f(X) is the generalized functional description. Theinput, i, is a secondary input used to initialize the block, provideinterim parametric storage, implement breakpoint capability, and so on.The secondary output, o, provides a reportable data path. The designerusing SLATE is responsible for defining the executable FDs, theinterconnections between host SLABs/FDs and the functional/processconsistency between FDs and among their interconnections. The functionf(X) may use local variables and parameters.

Text Fragments

FIGS. 9a-d illustrate the text fragments 94 and the automatic documentgeneration functions provided by SLATE. As previously discussed, anynumber of text fragments 94 may be associated with each SLAB 78. FIG. 9aillustrates a text fragment associated with the Product InventoryChamber SLAB 110. A Modify Text Fragment menu 192 is shown in FIG. 9a.The menu 192 provides a Name Field 194 for the name of the textfragment, a Numeric ID Field 196 for providing a numeric ID for the textfragment (an alternate name), a Description Field 198 for describing thetext fragment, a Key Word Field 200 for listing key words associatedwith the text fragment, an Attachment Field 202 specifying the SLAB towhich the text fragment is associated, a Referring Documents Field 204listing documents which incorporate the text fragment and a Edit Field206 displaying the content of the text fragment to be modified.

FIG. 9b is a Format Block menu for specifying parameters for a documentcomprising one or more text fragments 94. The menu 208 includes a NameField 210 for entering the name of the document to be generated, a TitleField 212 for providing a title for the document, a Document Type Field214 for specifying a document type (such as manual, statement of work,proposal, etc.), a Publisher Name Field 218, a Contract Name Field 220for specifying a particular contract with which the document isassociated, a Customer Field 222 for specifying the entity for which thedocument is being generated, a Revision Field 224 for specifying arevision identifier, a Date Field 226 for specifying the date of therevision, a Classification Field 228 for specifying a confidentialityclassification for the document, Header and Footer Fields 230, andDocument Support Fields 232 for whether the document contains a table ofcontents, index, acronym section, reference document section, list ofappendices, list of figures, or lists of tables.

FIG. 9c illustrates an Editor Menu 234 for constructing a template forthe document. A Name Field 236 provides the name of the document.Document Title Field 238, Revision Field 240, Date Field 242, andClassification Field 244 have the same functions as described inconnection with FIG. 9b. The Structure Field 246 allows the user toprovide a template describing the organization of the document and thereferenced text fragments. For example, under section three ("ProductInventory Chamber"), the text fragment "Chamber" is referenced. Thistext fragment is shown in FIG. 9a.

In FIG. 9d, the merged output based on the document template isillustrated. The file name is provided in Name Field 248 and the text isprovided in Text Field 250. As can be seen, various files have beenmerged into the template shown in FIG. 9c. The merged document providesa number of control commands such as "/BEGIN", "/DOCT", and "/TITLE". Inthe preferred embodiment, however, the merged document may be formattedto be compatible with the file specifications of any one of a number ofpopular word processors.

TRAMs

As previously discussed in connection with FIG. 4, a design may bestructured as a functional requirement definition (FRD) 68, separatedfrom one or more implementation logically mapped alternatives (ILMAs) 70by a functional-to-implementation mapping (FIM) 74. In practice, anumber of FIMs may exist, not only between the FRD and the ILMA, butalso between different levels of ILMAs. Anywhere there is a logical"leap of intuition" in synthesizing a solution, or anywhere an abstractconcept (function, algorithm or need) is mapped onto a system resource(for example, by assignment of ports, interrupt handlers, scheduling ofband width, etc.), a FIM exists, and the object for recording themapping in SLATE is a TRAM (Transitional Mapping).

FIG. 10 illustrates a TRAM 252. A TRAM 252 is a conduit to conveyfunctionality, requirements traceability, and technical allocationbudgets across FIMs 74 in the design structure. The TRAM 252 provides aspecial parent-child relationship, described herein as a "fosterparent-foster child" relationship between SLABs. The TRAM 252 links oneor more "foster" parent SLABs to one or more "foster" children SLABs.Each SLAB may be linked to one or more RTLs 90 and TABs 88 from thefoster parent SLABs and may have associated text fragments 94 whichdescribe the TRAM interlinks.

FIGS. 11a and 11b illustrate common uses of TRAMs 252. In FIG. 11a, acontrol hardware SLAB 254 and a process software SLAB 256 are coupledvia TRAM 258 to a microprocessor with ROM SLAB 260. This 2:1 mapping ofSLABs 254 and 256 to SLAB 260 could not be achieved using hierarchicaldecomposition, since SLATE allows any SLAB to have, at most, one parent.In the example of FIG. 11a, SLABs 254 and 256 are the foster parentSLABs and SLAB 260 is the foster child SLAB.

FIG. 11b illustrates a second example of a TRAM wherein a communicationschannel SLAB 262 is coupled to a queuing software SLAB 264, a queuinghardware SLAB 266, a protocol SLAB 268 and a bus hardware SLAB 270. Thecommunications channel SLAB 262 includes an RTL 272 and a radiation TAB274. The RTL 272 is transferred via the TRAM 276 to the foster childrenTABs 264-270. The radiation TAB 274 is allocated between the queuinghardware SLAB 266 and the bus hardware SLAB 270. The radiation TAB 274may be allocated in any desired ratio; for example, one-third of theallowable radiation associated with the communications channel could beallocated to the queuing hardware TAB 266 and two-thirds of theradiation could be allocated to the bus hardware SLAB 270.

In recording complex system designs, providing clear documentation ofthe thought processes behind the derivation of the details of animplementation from original requirements presents a major problem forthe system engineer. Major portions of the system's design descriptioncan normally be represented by a top-down hierarchical decomposition.SLATE uses such a hierarchical detail decomposition paradigm, withstandard SLAB parent-child relationship, to carry the bulk of mostsystem design descriptions. The difficulty occurs when standardhierarchical structure is not adequate to explain the complexitiesinvolved in relationships that have resulted in the final designembodiment. Typically, it is these precise complexities that are most inneed of explanation and supporting documentation, but for whichdesigners have historically had no special documentation tools to workwith. In the SLATE paradigm, the TRAM mechanism handles these complexrelationships.

At least three categories of complexities necessitate the TRAM structureas a supplement to the standard hierarchical SLAB structure. The threecategories are:

1. Mapping conceptual requirements onto implementable components andsubsystems. (This is the original SLATE "classic" TRAM, sometimesreferred to as "bridging the FIM".) This involves a shift of perspectivefrom a statement of need to a planned solution. Examples of the mappingof these conceptual requirements are shown in FIGS. 11a-b.

2. Mapping the merger of a secondary requirement onto an existingimplementable component(s) and/or subsystem(s) that was previouslydesigned to satisfy a different functional need. An example of thismapping is provided hereinbelow.

3. Remapping "current" perspective of a potentially implementablestructure onto a different set of implementables that are "closer to"the final design implementation. This category is subtle to grasp,because it is natural in the SLATE paradigm to think about onehierarchical structure of implementables. In practice, a solution isformed by "nibbling" away at the total picture until it can be brokendown into digestible bits and pieces. Thus, in the interim process of"getting to a design solution", the system designer travels through manyintermediate steps that help redefine the need in terms closer to whatwill finally be implemented. A common occurrence of this categoryinvolves gathering up multiple uses of shared resources and coalescingthe need into a common design embodiment. Since the individual usagepoints are never implemented, it is not correct to think of the SLABs inwhich they are identified as "implementables" (even though they couldhave been implemented individually in place, and even if every otherSLAB in the hierarchical structure is the final design embodiment)because, as used in context, these SLABs form a needs requirement thatwill be met in the final design by implementing a shared resource.

Much of what has previously been written about SLATE has postulated theexistence of an extensive detailed requirements list. The example givenbelow has been chosen to illustrate how the same process evolves evenfrom loosely stated "mission statements" that are representative ofcommercial undertakings. The example selected involves designing anautomobile.

A partial list of the rationale and requirements driving a commercialmanufacturer in its design of automotive vehicles might be stated as:

"We intend to offer a viable product for sale on the commercial marketby:

* Meeting governmental requirements that allow the product to be sold.

* Meeting functional requirements and needs of our customer base.

* Appealing to the potential customers' `care abouts`."

Such a requirements list can be mapped into a "Functional RequirementsDefinition" structure shown in TABLE 2, and broken down hierarchicallyinto finer detail. Each hierarchical line entry in the following couldcorrespond to a SLAB in SLATE.

                  TABLE 2                                                         ______________________________________                                        Functional Requirements Definition                                            ______________________________________                                        1.      Offer a viable product for sale on the                                        commercial market.                                                    1.1     Meet governmental requirements to allow product                               to be sold.                                                           1.1.1   Meet Safety Standard.                                                 1.1.2   Meet Environmental Pollution Standards.                               . . .                                                                         1.2     Meet functional needs of customer base.                               1.2.1   Cargo Capacity.                                                       1.2.2   Operational Speed.                                                    1.2.2.1 Horsepower of Engine.                                                 1.2.2.2 Weight of Vehicle.                                                    1.2.3   Operational Range on single tank of gas.                              . . .                                                                         1.3     Appeal to customers' "care abouts".                                   1.3.1   Supply Comfort.                                                       1.3.2   Supply "Ease of Handling".                                            1.3.3   "Eye Catching" Design.                                                1.3.4   Minimize "Cost of Operation".                                         1.3.4.1 Maximize "Miles per Gallon".                                          . . .                                                                         ______________________________________                                    

Further breakdown might be done in any given area (for example, under1.2.2 Operational Speed, further detailing down to mathematicalrelationships between weight, horsepower, aerodynamic quality of design,etc., might be comprehended). However, a top-down refinement will notreach a design for an automobile, because the functional requirementsdefinition hierarchy does not deal with "implementables". Nocarburetors, no tires, no pistons, no windshield wipers or tail lightsare provided for. Clearly a TRAM mapping must exist between the elementsout of which the automobile is built and the functional requirementsdefinition provided in Table 2.

The implementation can also be described in a similar hierarchicalstructure provided in TABLE 3. One such structure, in part, might bedetailed as follows:

                  TABLE 3                                                         ______________________________________                                        Implementation Hierarchical Structure                                         ______________________________________                                        1.          Automobile.                                                       1.1         Structural Body/Chassis.                                          1.2         Interior Passenger Chamber.                                       1.3         Engine.                                                           1.3.1       Engine Block.                                                     1.3.2       Carburetor.                                                       1.3.3       Radiator/Cooling System.                                          1.3.3.1     Fan.                                                              1.3.3.2     Water Pump.                                                       1.3.3.3     Heater.                                                           1.3.3.4     Defroster.                                                        1.3.3.5     Radiator                                                          1.4         Power Train.                                                      1.5         Exhaust System.                                                   1.5.1       Tail Pipe.                                                        1.5.2       Muffler.                                                          1.5.3       Catalytic Converter.                                              1.6         Electrical System.                                                1.6.1       Battery.                                                          1.6.2       Alternator.                                                       1.6.3       Lights.                                                           1.7         Optional Features.                                                1.7.1       Power Steering.                                                   1.7.2       Cruise Control.                                                   1.7.3       Air Conditioner                                                   . . .                                                                         ______________________________________                                    

As in the prior hierarchy, the choices are subjectively grouped, and nosingle embodiment of "associations" should be considered "correct".Rather it should be regarded as a documented record of the perspectivein which the designer viewed the system.

Within SLATE, the TRAM mechanism is used to construct the mappingbetween the functional requirements definition and the implementationhierarchy. For the automotive design example, the SLATE design scenariomight be:

Construction of TRAMs

The user already has the two SLAB hierarchies illustrated above inTables 2 and 3 to work with. The user then selects the "Action/Object"command "Add/TRAM". A Pop-up Window opens that allows the user tospecify the particulars of this TRAM. The TRAM will be given a name thatthe user can reference it by. The input side connections (foster parentSLAB(s)) from the Functional Requirements Definition hierarchy in thisexample) are specified. The output side connections ("adoptedchild(ren)) SLAB(s)" in the Implementation hierarchy in this example arespecified. At this point, the new TRAM is established and "lives" in theDatabase in much the same manner as a normal SLAB does.

Having established the TRAM, the user is then free to "enhance" it in amanner very similar to what he/she would do if it were a standard SLAB.The user can "Add/Text Fragment" to explain the thought process behindthe mapping carried via the TRAM. The user can "reroute" TABs that areattached to the TRAM's foster parents, to flow wholly or partiallythrough the TRAM (by controlling TAB propagation at the foster parentSLAB) and then appropriately routing the portion of the TAB propagatedinto the TRAM, at the TRAM itself. "Requirement Traceability Links" canbe either attached (mouse clicks tieing requirement to TRAM) orpropagated through the TRAM (standard RTL propagation window usage onboth the foster parent SLAB(s) and TRAM).

Using the automotive example, the user might call out the following:

ADD-TRAM . . . TRAM Name=PASSENGER RESTRAINT SYSTEM

Foster Parent SLABs=SAFETY STANDARD XXX (1.1.1.8.4) PASSENGER COMFORT(1.3.1.6)

Adopted Child SLAB=AIR BAG (1.2.8.3.9)

A text fragment might be placed on this TRAM explaining that the Air Bagis judged more comfortable than harnesses per a consumer survey. Adifferent model car might have economy requirements outweighing comfort,and opt for shoulder harnesses. Still others might bring economy, safetyand comfort together at this TRAM, and offer the customer a standardshoulder harness or optional air bag system. Whatever the structure oroutcome, the TRAM documents the reasoning that lead to the designimplementation, and provides traceability both to and from the factorsthat were considered in the design process.

The Passenger Restraint TRAM has a single adopted child, and multiplefoster parents. It is referred to as an "N-to-1" TRAM because it maps aplurality of foster parents (Safety Standards and Passenger Comfort),transition mapping onto a single adopted child (Air Bag). The "N-to-1"TRAMs are the most obvious TRAMs in the design, because a SLAB, bydefinition, can have, at most, one parent. Therefore, if multipleconcerns are focusing together to result in a single implemented entity,the SLAB is not just a detailed refinement of previously explainedconcepts, but instead constitutes a synthesis of multiple ideas thathave been developed (a new perspective), and must be mapped via TRAM(s)to clearly delineate the intended relationships. The TRAM example abovefits nicely into the category 1 TRAM rationalization.

Somewhat more subtle is the "1-to-N" TRAM, where a single fosterparent's attributes are tied to numerous adopted children as shown inFIG. 11a. This is sometimes confused with the normal hierarchicalparent-child relationship (as shown in FIG. 6), and at times spawnsquestions about the need for a "1-to-N" TRAM. The answer lies in "theChange of Perspective" and can best be explained by example. Considerthe following:

    ______________________________________                                        TRAM Name = CHOICE OF NON-TOXIC MATERIALS                                     Foster Parent SLAB =                                                                        SAFETY REGULATION REQUIR-                                                     ING NON-INFLAMMABLE                                                           MATERIAL USAGE (1.1.1.3.5)                                      Adopted Children SLABs =                                                                      SEAT UPHOLSTERY                                                               MATERIAL (1.2.8.3.5.9)                                                        RADIATOR HOSES (1.3.3.6)                                                      EXTERIOR VINYL TRIM                                                           (1.7.6.2)                                                                     . . . ETC. . . .                                              ______________________________________                                    

Clearly, the radiator hoses are not included "just to have non-toxicmaterial usage". Their primary function is to carry fluids in thecooling system (hence their direct ancestry passes through SLAB1.3.3--Radiator/Cooling System). In this example, numeric technicalbudgets are not appropriate, as no numeric quantification is present,nor distributed, Attempting to relegate the Non-Inflammable MaterialUsage to a compliancy checklist would dilute the detail of this designstructure, afforded by using a "1-to-N" TRAM. This is a category 2utilization of TRAMs.

When both the driving needs and the resultant implemented structures aredistributed, the TRAM becomes an "N-to-M" mapping. For example, theelectronic systems in automobiles have grown in their sophistication,the need to communicate status information and commands throughout theautomobile has become complex enough that some automobiles now have aninternal "data bus" routed throughout the car. An associated "N-to-M"TRAM in the design of such an information bus might be described as:

    ______________________________________                                        TRAM Name = AUTOMOTIVE INFORMATION BUS                                        Foster Parent SLABs =                                                                       Sensory data on air/fuel mix                                                  Sensory data on engine timing                                                 Sensory data on emissions                                                     Sensory data from "Gas Pedal                                                  Position"                                                                     Sensory data from "Brake Pedal                                                Position"                                                                     Sensory data from Speedometer                                                 Sensory data about oncoming                                                   lights                                                                        Sensory status of headlight                                                   beams                                                                         Control Microprocessor                                                        Algorithms                                                      Adopted Children SLABs =                                                                      Electrical Data Bus Cabling                                                   Microprocessor (with software in                                              ROM)                                                                          Bus multiplexer hardware                                                      various sensors . . .                                                         various actuators . . .                                                       . . . etc. . . .                                              ______________________________________                                    

There are many points to be made about this TRAM. The first is that itclearly constitutes "an assemblage of components to perform severalfunctional tasks", a statement that is probably true of all "N-to-M"TRAMs. Since it is an "assemblage of components" it is conceivable thatit could be thought of as a subsystem, contracted out, and become inessence, an "off-the-shelf" component. Such changes of perspectiveshould not be surprising, since even the automobile itself could beviewed as a component in some higher level systems. Therefore, the TRAMdocuments the perspective being dealt within a relative context, and theinformation contained therein must be considered within that context tobe properly understood. No value judgment is assigned to theperspective.

There is a commonly occurring theme in many system designs involvingmultiple usage of a reusable/shareable resource (such as a hardware bus,or a software subroutine). Implementing each occurrence separately (aswould be demanded in the strictest sense under a tops-down hierarchicaldesign structure) normally runs counter to the almost universalrequirement of maximizing efficiency by minimizing cost. The gatheringup of these multiple occurrences, and implementing a smaller number ofresource suppliers (often just one), constitutes a change inperspective, and necessitates a TRAM. Significantly, it will appear thatsuch a TRAM maps from one view of the implementation to another view ofthe implementation. In actuality, the first hierarchical structure is amixture of implementables and "functional needs". The remapping of the"structural points needing usage of the functional resource" to aperspective that will be implemented as a shared resource via a TRAMconfirms that the intermediate hierarchical structure is not "purelyimplementables", or at least not with relation to the final systemdesign being implemented.

MORTAR

Once the FIM region has been traversed via TRAMS that computationallylink allocatable requirements, structural requirements andimplementation structures as well as documenting the underlyingconsiderations, attention can then be paid to documenting the macrolevel synergistic effects that may occur at a FIM. The SLATE mechanismfor explaining the macro synergistic considerations is MORTAR (MappingOf Regional TRAMs and Requirements).

MORTAR provides the structure to bind together the synergisticrelationships inherent in a set of TRAMs. The MORTAR is actuallycomposed of supportive textual description and quantitative matrixdescriptors that explain synergistic effects occurring between and amongthe TRAMs. These types of relationships are especially important todocument when the FIM mapping is actually undergoing multipleconstraints, and the resultant implementation choices are multiply boundin subtle, secondary manners, a condition that is at the heart and coreof "concurrent engineering".

An illustrative example at this point will clarify many points and offera reference situation against which some of the concepts can be morefully elaborated. Consider the following example:

Needed Functionality:

Design a system that sorts, classifies and correlates "items".

Constraints:

System cannot weight more than 70 oz. nor use more than 5 amps, and mustprocess at least 6000 "items"/second.

Requirements List (derived from above):

R1--Sort

R2--Classify

R3--Correlate

R4--<70 oz.

R5--<5 amps

R6--6000 items/sec.

Potential "System Components" in implementing a solution:

                  TABLE 4                                                         ______________________________________                                        Electronic Chips                                                              TYPE         MIPS    WEIGHT    POWER  COST                                    ______________________________________                                        Microprocessor XYZ                                                                         6.5     4.5 oz    400 ma $ 38.75                                 Microprocessor RST                                                                         8.2     6.2 oz    750 ma $ 46.20                                 Microprocessor JKL                                                                         3.5     3.4 oz    350 ma $ 14.50                                 256K DRAM    --      2.5 oz    160 ma $  1.38                                 1 Meg DRAM   --      4.9 oz    425 ma $ 12.42                                 ______________________________________                                    

                  TABLE 5                                                         ______________________________________                                        Software Algorithmic Components                                                               COMPAT-   EXCLUSIVE INSTR                                                     IBLE      MEMORY    EXECUTED                                  ID   FUNCTION   WITH      NEEDS     PER ITEM                                  ______________________________________                                        J14  Sort       RST        4 Meg     84                                       J93  Sort       JKL        2 Meg    134                                       J42  Sort       XYZ        1 Meg    272                                       C15  Classify   JKL, XYZ   40K       93                                       C15  Classify   RST        58K       75                                       C88  Classify   XYZ       825K       26                                       S71  Correlate  JKL, RST   4 Meg    852                                       S64  Correlate  XYZ        14 Meg   148                                       ______________________________________                                    

SLATE may accommodate numerous interpretations and approaches to eachdesign, and there is not a single "right" approach. The definition ofhow TRAMs are defined and mapped reflect the individual design approachof the user, and must be complete and consistent within the frameworkthat the design is viewed by the user. In essence, the TRAMs capture theperspective view that the designer intended. Alternate views may beequally valid. The example continues with one possible perspective thatworks.

    ______________________________________                                                       Weight Power    Cost                                           ______________________________________                                        Solution 1: (Least Expensive)                                                 Microprocessor - JKL, Qty 2                                                                     6.8 oz  0.7 a    $ 29.00                                    DRAMs - 256K, Qty 25                                                                           62.5 oz  4.0 a    $ 34.50                                    Software - J93, C15, & S71                                                    Resulting Solution Processes 6481+ items per second.                          Solution 2: (More Expensive, but less power & weight)                         Microprocessor - JKL, Qty 2                                                                     6.8 oz  0.7  a   $ 29.00                                    DRAMs - 1 Meg., Qty 7,                                                                         34.3 oz  2.975 a  $ 86.94                                    Software - J93, C15, & S71                                                    Resulting Solution Processes 6481+ items per second.                          Solution 3: (Faster, better throughput at a higher cost)                      Microprocessor - RST                                                                            6.2 oz  0.75  a  $ 46.20                                    DRAMs - 1 Meg, Qty 9                                                                           44.1 oz  3.825 a  $111.78                                    Software - J14, C15, & S71                                                    Resulting Solution Processes 6923+ items per second.                          ______________________________________                                    

There are a number of other potential solutions if we use a mixture of256 k and 1 Meg DRAMs, that on a sliding scale would cut cost, but wouldalso affect weight and power consumption. For example:

    ______________________________________                                        Solution 3A: (Same throughput, less weight, power & expense)                                Weight  Power    Cost                                           ______________________________________                                        Microprocessor - RST                                                                          6.2 oz    0.75 a   $ 46.20                                    DRAMs - 1 Meg, Qty 8                                                                          39.2 oz   3.4  a   $ 99.36                                    DRAMs - 256k, Qty 1                                                                           2.5 oz    0.16 a   $  1.38                                    Software - J14, C15 & S71                                                     Resulting Solution Processes 6923+ items per second.                          ______________________________________                                    

At this level of analysis Solution 3A appears superior to Solution 3,but in reality, the complications of mixing different sized memories andthe resulting weight, power and expense of support circuitry might ruleout 3A. Assuming that mixing memory sizes is acceptable, having seenacross the board improvement in weight, power and cost, the naturalinclination is to substitute the 256 k DRAMs for all the 1 Meg DRAMs.What worked nicely for a 1-to-1 chip substitution (because both the 1Meg and 256 k DRAMs contain more than enough to cover the C15/58k need)breaks down when a 4-to-1 chip substitution is needed. The applicabledeltas for each 1 Meg of substitution becomes:

Weight--Increases by 5.1 oz,

Power--Increases by 0.215 amps, and

Cost--Decreases by $ 6.90.

While the decreasing cost is desirable, the weight and/or power limitswill soon prevent further substitution of 256 k DRAMs into an RST basedsolution.

Supplemental Requirements:

RS1--Need for a microprocessor to run all software

RS2--Memory requirements for SORT SW

RS3--Memory requirements for CLASSIFICATION SW

RS4--Memory requirements for CORRELATION SW

To carry through this example, one possible variation of the resultantTRAMs associated with ILMA 2 (Solution 2) are provided below:

T1{(R1)→(J93)} Sort SW from requirement to sort

T2{(R2)→(C15)} Classification SW from req. to classify

T3{(R3)→(S71)} Correlation SW from requirement to corr.

T4{(RS1)→(JKL)} Microprocessor from req. to run software

T5{(RS2, RS3, RS4)→(DRAMs)} Total memory needs

There are still several questions unresolved with this TRAM mapping.First, the system engineer must instruct SLATE to deal with the dualarchitecture of the parallel JKL processors. Probably the simplestacceptable method would be to have a single SLAB (perhaps named "JKL")that represented the "complete" microprocessor functionality. This SLAB("JKL") would then have children that would be the two instances ofmicroprocessor occurrence (SLABs "JKL1" and "JKL2"), along with anyother circuitry needed to distribute and balance the processing tasksbetween the twin processors. T4 would be pointing at the functionalmicroprocessor SLAB ("JKL").

The other logical question is how to tie in the allocatable requirements(R4, R5 and R6). It is not unreasonable to introduce a sixth TRAM to mapthe hardware requirements onto the hardware, e.g.:

    T6{(R4, R5)→(JKL, DRAMs)} HW constraints from req. limits

R6, the requirement that the system process 6000 items/sec., however,remains to be accounted for. An artificial "System" SLAB could beintroduced at the highest level, just to map it out of the TABDefinition Table. However, it would be difficult to allocate this"Throughput" TAB to lower SLABs. This "distributed allocatable" (R6) isindicative that the "whole picture" is not yet present, because as wasseen in the analysis portion, many subtle linkages are in effect betweenthe TRAMs that must be balanced to reach this solution. Thedocumentation of these TRAM linkages is provided for in MORTAR, and itis the MORTAR that should properly be the recipient of R6 in this case.It should be noted that each MORTAR must belong to an ILMA to reflectthe unique sets of TRAMs within its implementation structure.

The core of the MORTAR is its matrix of TRAM relationships. The matrixis composed of all TRAMs within the set being described by the MORTAR,mapped against themselves. Thus, for a set of "n" TRAMS, the MORTARmatrix is "n" ×"n" containing "n" squared elements. Any relationalmappings are placed in appropriate elements of the matrix. Because sucha matrix is mirrored along its diagonal (containing redundantinformation), only the diagonal and one of the remaining triangularareas need be specified. By convention, the lower triangular area isfilled in for MORTAR matrices. MORTAR appears to the designer in aspreadsheet form shown in FIG. 12.

The MORTAR matrix concisely shows all the interdependencies that areapplicable for a set of TRAMs selected by the designer. For the Sort SW(T1), it shows that the choice of J93 is tied to JKL microprocessor, itrequires 2 Megs of memory, and it will consume 0.81 MIPS of processing.The JKL microprocessor (T4) is shown to have 3.5 MIPS and that a dualpair is used resulting in 67.8 oz of weight and 700 ma of powerconsumption. Likewise, it is shown that 7 1-Meg DRAMs (T5) are needed,and their contribution in weight and power consumption are listed. R6can now be directly tied to this MORTAR. Text fragments supporting thisMORTAR would expound upon the interdependencies and record details ofalternatives considered, and why they were not chosen.

The MORTAR matrix is utilized whenever a change is to be considered. Byscanning the row and column for any pertinent TRAM, all dependencies canbe checked against for synergistic impact. For example, if someone wereto propose using a new faster correlation software routine, the T3column reveals that the appropriate questions to be considered are:

1. How many MIPS are needed to execute it to our basic R6 requirement?

2. Will it run on the JKL processor?

3. How much memory will it take?

No additional questions are generated by scanning the T3 row because theprior TRAMs (T1 & T2) are not directly dependent on T3 (null entries).

By answering all of these questions, a correct analysis can be made ofthe overall impact introducing the new software will have. If the newsoftware needed less MIPS, ran on JKL, and did not use much more memorythen it would be a very interesting candidate for replacing S71.

In addition to illustrating all the dependencies between TRAMs, a MORTARmatrix is further capable of performing row, column and matrixoperations on the various cells. For example, a cell providing acalculation for the needed MIPS according to TRAMs T1, T2 and T3 couldbe performed by calculating the sum of cells T1-T1, T2-T2 and T3-T3. Atotal weight cell could be provided by adding the weight specified incells T6-T4 and T6-T5.

Even more interesting, from the standpoint of understanding how MORTARfacilitates the analysis of design change impact, is the potentialeffect of new software that needs substantially less MIPS, less memory,but cannot run on JKL. This scenario would then force the designer toconsider changing the microprocessor (T4), which sends him/her back tothe MORTAR matrix to determine what needs to be considered when T4 ischanged. That would generate the next set of questions, which are:

1. Does J93 run on the alternate processor?

2. Does C15 run on the alternate processor?

3. What MIP rate does the alternate processor run at?

4. What weight and power consumption will the alternate processor use?

The microprocessor change, by itself, does not affect the memoryconsiderations. However, if these questions "domino" into consideringfurther software changes (because either or both J93 and/or C15 do notrun on the alternate processor), then memory considerations will reenterthe analysis process when the next level of questions are generated fromappropriate row/column entries under T1 and/or T2.

Finally, consider the potential impact if a new 4 Meg DRAM were tobecome available that effectively removed the original barriers(exceeding R4 and R5) that precluded using S64:

    ______________________________________                                        Type       MIPS     Weight   Power  Cost                                      ______________________________________                                        4 Meg DRAM --       6.3 oz   485 ma $ 28.00                                   Solution 4:                                                                                    Weight   Power    Cost                                       ______________________________________                                        Microprocessor - XYZ                                                                            4.5 oz  0.4  a   $ 38.75                                    DRAMs - 4 Meg, Qty 4                                                                           25.2 oz  1.94 a   $112.00                                    Software - J42, C88, & S64                                                    Resulting Solution Processes 15695+ items per second.                         RESULTING POSSIBLE SOLUTIONS:                                                 Solution Number                                                                           Cost     Weight  Power  Items/Sec.                                ______________________________________                                        1           $ 63.50  69.3 oz 4.7  a 6481                                      2           $115.94  41.1 oz 3.675 a                                                                              6481                                      3           $156.98  50.3 oz 4.575 a                                                                              6923                                       .sup. 3A   $146.94  47.9 oz 4.31  a                                                                              6923                                      4           $150.75  29.7 oz 2.34  a                                                                              15695                                     ______________________________________                                    

If all the above examples were documented in MORTAR, entries in thematrices would establish the relationship between the microprocessor,memory, and software routines that would not allow arbitrary changes toany of the components without appropriate analysis of the impact on theothers. The entries in the matrices would indicate which parametricvalues were being balanced (e.g., board area occupied by chips would notbe a constraint in this example) and only the relevant parameters wouldneed to be analyzed.

In addition to the relationship matrix shown above, a shadow matrixcould be implemented to carry the actual realized numeric values,allowing computation of the impact of substitutions across an entiresystem database, and load up analysis programs with libraries ofalternative components for overnight batch analysis runs searching formore optimal alternatives. This concept is only possible if the MORTARrelationship are captured and structured, suitable for computationalanalysis.

The present invention provides numerous advantages over the prior art.Since SLATE handles a wide range of hierarchical levels, a consistentset of tools may be provided for the entirety of a project. Compliancy,structural and allocatable requirements may be carried through multiplelevels to allow the system designer to identify problem areas and toidentify over allocated areas which may be used to solve allocationproblems. SLATE allows requirements to flow down and implementationdetails to flow up, thereby providing the system designer with a broadunderstanding of the entire system. As implementations change, theaccounting of the actual values for the technical allocatable budget maybe automatically recalculated.

Further, the TRAM mechanism provided in SLATE encourages documentationof implementation complexities. The relations between TRAMs aredocumented in MORTAR matrices, providing a means for discerning theintricacies of a proposed implementation change.

Although the present invention and its advantages have been described indetail, it should be understood that various changes, substitutions andalterations can be made herein without departing from the spirit andscope of the invention as defined by the appended claims.

What is claimed is:
 1. A method of system design for a system, using acomputer, comprising the steps of:generating a first set of objects eachdefining a portion of the system, a parent object of the objects havinga parent-child relationship wherein one or more child objects eachdefine a portion of the parent object; generating a second set ofimplementable objects associated with said first set of objects;generating active links between said first set of objects and saidsecond set of implementable objects, said active links describing therelationship between said first set and said second set and mappingrequirements of said relationship between said first set and said secondset to determine improper implementable objects, and wherein said activelink generating step includes the step of providing text filesassociated with said active links.
 2. The method of claim 1, whereinsaid step of generating a first set of objects comprises the step oflimiting said first set of objects to a single object and said step ofgenerating a second set of objects comprises the step of defining saidsecond set of objects as a plurality of objects.
 3. The method of claim1, wherein said step of generating a first set of objects comprises thestep of defining said first set of objects as a plurality of objects andsaid step of generating a second set of objects comprises the step oflimiting said second set of objects to a single object.
 4. The method ofclaim 1, wherein said step of generating a first set of objectscomprises the step of defining said first set of objects as a pluralityof objects and said step of generating a second set of objects comprisesthe step of defining said second set of objects as a plurality ofobjects.
 5. The method of claim 1, wherein said step of generating afirst set of objects comprises the step of generating a first set ofimplementable objects.
 6. The method of claim 1, wherein said step ofgenerating a first set of objects comprises the step of generating afirst set of conceptual requirements.
 7. A method of system design for asystem, using a computer, comprising the steps of:generating a first setof objects each defining a portion of the system, a parent object of theobjects having a parent-child relationship wherein one or more childobjects each define a portion of the parent object; generating a secondset of implementable objects associated with said first set of objects;generating active links between said first set of objects and saidsecond set of implementable objects, said active links describing therelationship between said first set and said second set and mappingrequirements of said relationship between said first set and said secondset to determine improper implementable objects; and apportioningallocatable requirements to said first and second sets of objects,wherein said step of link generating includes the step of tracing theapportionment of allocatable requirements associated with said first setof objects among said second set of objects.
 8. A method of systemdesign for a system design for a system, using a computer, comprisingthe steps of:generating a first set of objects each defining a portionof the system, using a parent object of the objects having aparent-child relationship wherein one or more child objects each definea portion of the parent object; generating a second set of implementableobjects associated with said first set of objects; generating activelinks between said first set of objects and said second set ofimplementable objects, said active links describing the relationshipbetween said first set and said second set and mapping requirements ofsaid relationship between said first set and said second set todetermine improper implementable objects; and associating structuralrequirements to said first set of objects, wherein said step of linkgenerating includes the step of allocating the structural requirementsto one or more of the objects associated with said second set ofobjects.